// See LICENSE for license details. #include #include #include "platform.h" #include #include "plic_driver.h" #include "encoding.h" #include #define RTC_FREQUENCY 32768 void reset_demo (void); // Structures for registering different interrupt handlers // for different parts of the application. typedef void (*function_ptr_t) (void); void no_interrupt_handler (void) {}; function_ptr_t g_ext_interrupt_handlers[PLIC_NUM_INTERRUPTS]; // Instance data for the PLIC. plic_instance_t g_plic; // Simple variables for LEDs, buttons, etc. volatile unsigned int* g_output_vals = (unsigned int *) (GPIO_BASE_ADDR + GPIO_OUTPUT_VAL); volatile unsigned int* g_input_vals = (unsigned int *) (GPIO_BASE_ADDR + GPIO_INPUT_VAL); volatile unsigned int* g_output_en = (unsigned int *) (GPIO_BASE_ADDR + GPIO_OUTPUT_EN); volatile unsigned int* g_pullup_en = (unsigned int *) (GPIO_BASE_ADDR + GPIO_PULLUP_EN); volatile unsigned int* g_input_en = (unsigned int *) (GPIO_BASE_ADDR + GPIO_INPUT_EN); /*Entry Point for PLIC Interrupt Handler*/ void handle_m_ext_interrupt(){ plic_source int_num = PLIC_claim_interrupt(&g_plic); if ((int_num >=1 ) && (int_num < PLIC_NUM_INTERRUPTS)) { g_ext_interrupt_handlers[int_num](); } else { exit(1 + (uintptr_t) int_num); } PLIC_complete_interrupt(&g_plic, int_num); } /*Entry Point for Machine Timer Interrupt Handler*/ void handle_m_time_interrupt(){ clear_csr(mie, MIP_MTIP); // Reset the timer for 3s in the future. // This also clears the existing timer interrupt. volatile uint64_t * mtime = (uint64_t*) (CLINT_BASE_ADDR + CLINT_MTIME); volatile uint64_t * mtimecmp = (uint64_t*) (CLINT_BASE_ADDR + CLINT_MTIMECMP); uint64_t now = *mtime; uint64_t then = now + 1.5 * RTC_FREQUENCY; *mtimecmp = then; // read the current value of the LEDS and invert them. uint32_t leds = *g_output_vals; *g_output_vals ^= ((0x1 << RED_LED_OFFSET) | (0x1 << GREEN_LED_OFFSET) | (0x1 << BLUE_LED_OFFSET)); // Re-enable the timer interrupt. set_csr(mie, MIP_MTIP); } const char * instructions_msg = " \ \n\ SIFIVE, INC.\n\ \n\ 5555555555555555555555555\n\ 5555 5555\n\ 5555 5555\n\ 5555 5555\n\ 5555 5555555555555555555555\n\ 5555 555555555555555555555555\n\ 5555 5555\n\ 5555 5555\n\ 5555 5555\n\ 5555555555555555555555555555 55555\n\ 55555 555555555 55555\n\ 55555 55555 55555\n\ 55555 5 55555\n\ 55555 55555\n\ 55555 55555\n\ 55555 55555\n\ 55555 55555\n\ 55555 55555\n\ 555555555\n\ 55555\n\ 5\n\ \n\ SiFive E-Series Software Development Kit 'demo_gpio' program.\n\ Every 1.5 second, the Timer Interrupt will invert the LEDs.\n\ (Arty Dev Kit Only): Press Buttons 0, 1, 2 to Set the LEDs.\n\ \n\ "; void print_instructions() { write (STDOUT_FILENO, instructions_msg, strlen(instructions_msg)); } void button_0_handler(void) { // Red LED on * g_output_vals |= (0x1 << RED_LED_OFFSET); // Clear the GPIO Pending interrupt by writing 1. GPIO_REG(GPIO_RISE_IP) = (0x1 << BUTTON_0_OFFSET); }; void button_1_handler(void) { // Green LED On * g_output_vals |= (1 << GREEN_LED_OFFSET); GPIO_REG(GPIO_RISE_IP) = (0x1 << BUTTON_1_OFFSET); }; void button_2_handler(void) { // Blue LED On * g_output_vals |= (1 << BLUE_LED_OFFSET); GPIO_REG(GPIO_RISE_IP) = (0x1 << BUTTON_2_OFFSET); }; void reset_demo (){ // Disable the machine & timer interrupts until setup is done. clear_csr(mie, MIP_MEIP); clear_csr(mie, MIP_MTIP); for (int ii = 0; ii < PLIC_NUM_INTERRUPTS; ii ++){ g_ext_interrupt_handlers[ii] = no_interrupt_handler; } #ifdef HAS_BOARD_BUTTONS g_ext_interrupt_handlers[INT_DEVICE_BUTTON_0] = button_0_handler; g_ext_interrupt_handlers[INT_DEVICE_BUTTON_1] = button_1_handler; g_ext_interrupt_handlers[INT_DEVICE_BUTTON_2] = button_2_handler; #endif print_instructions(); #ifdef HAS_BOARD_BUTTONS // Have to enable the interrupt both at the GPIO level, // and at the PLIC level. PLIC_enable_interrupt (&g_plic, INT_DEVICE_BUTTON_0); PLIC_enable_interrupt (&g_plic, INT_DEVICE_BUTTON_1); PLIC_enable_interrupt (&g_plic, INT_DEVICE_BUTTON_2); // Priority must be set > 0 to trigger the interrupt. PLIC_set_priority(&g_plic, INT_DEVICE_BUTTON_0, 1); PLIC_set_priority(&g_plic, INT_DEVICE_BUTTON_1, 1); PLIC_set_priority(&g_plic, INT_DEVICE_BUTTON_2, 1); GPIO_REG(GPIO_RISE_IE) |= (1 << BUTTON_0_OFFSET); GPIO_REG(GPIO_RISE_IE) |= (1 << BUTTON_1_OFFSET); GPIO_REG(GPIO_RISE_IE) |= (1 << BUTTON_2_OFFSET); #endif // Set the machine timer to go off in 3 seconds. // The volatile uint64_t * mtime = (uint64_t*) (CLINT_BASE_ADDR + CLINT_MTIME); volatile uint64_t * mtimecmp = (uint64_t*) (CLINT_BASE_ADDR + CLINT_MTIMECMP); uint64_t now = *mtime; uint64_t then = now + 1.5*RTC_FREQUENCY; *mtimecmp = then; // Enable the Machine-External bit in MIE set_csr(mie, MIP_MEIP); // Enable the Machine-Timer bit in MIE set_csr(mie, MIP_MTIP); // Enable interrupts in general. set_csr(mstatus, MSTATUS_MIE); } int main(int argc, char **argv) { // Set up the GPIOs such that the LED GPIO // can be used as both Inputs and Outputs. #ifdef HAS_BOARD_BUTTONS * g_output_en &= ~((0x1 << BUTTON_0_OFFSET) | (0x1 << BUTTON_1_OFFSET) | (0x1 << BUTTON_2_OFFSET)); * g_pullup_en &= ~((0x1 << BUTTON_0_OFFSET) | (0x1 << BUTTON_1_OFFSET) | (0x1 << BUTTON_2_OFFSET)); * g_input_en |= ((0x1 << BUTTON_0_OFFSET) | (0x1 << BUTTON_1_OFFSET) | (0x1 << BUTTON_2_OFFSET)); #endif * g_input_en &= ~((0x1<< RED_LED_OFFSET) | (0x1<< GREEN_LED_OFFSET) | (0x1 << BLUE_LED_OFFSET)) ; * g_output_en |= ((0x1<< RED_LED_OFFSET)| (0x1<< GREEN_LED_OFFSET) | (0x1 << BLUE_LED_OFFSET)) ; * g_output_vals |= (0x1 << BLUE_LED_OFFSET) ; * g_output_vals &= ~((0x1<< RED_LED_OFFSET) | (0x1<< GREEN_LED_OFFSET)) ; /************************************************************************** * Set up the PLIC * *************************************************************************/ PLIC_init(&g_plic, PLIC_BASE_ADDR, PLIC_NUM_INTERRUPTS, PLIC_NUM_PRIORITIES); reset_demo(); while (1); return 0; }